neurological disease

Biological and Pathophysiological Functions of Apolipoprotein E

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Areas of InvestigationResearch in our laboratory focuses on the biological and pathophysiological functions of apolipoprotein (apo) E. Long-term goals of our research are to understand the molecular and cellular mechanisms by which apoE4 increases the risk of Alzheimer’s disease (AD) and related neurodegenerative disorders and to develop therapeutic strategies.

SignificanceHuman apoE has three common isoforms (apoE2, apoE3 and apoE4) with different effects on lipid and neuronal homeostasis. ApoE4, the major known genetic risk factor for AD, increases the occurrence and lowers the age of onset of the sporadic and some familial forms of AD.

In most clinical studies, apoE4 carriers account for 65–80% of all AD cases, highlighting the importance of apoE4 in AD pathogenesis. Emerging data suggest that apoE4, with its multiple cellular origins and multiple structural and biophysical properties, contributes to AD by interacting with different factors through various pathways. However, the exact mechanisms underlying apoE4’s contribution to AD are still unclear.

ApproachesWe use neuronal cultures, iPS cell technology, and transgenic and gene-targeted mouse models to study the different effects of apoE3 and apoE4 on cell signaling pathways and cytoskeletal structure and function at molecular, cellular and behavioral levels. We also use these approaches to develop and evaluate novel treatment strategies for apoE4-related neurodegenerative disorders.

Based on these in vitro and in vivo observations, we hypothesize that apoE4 produced in neurons in response to stress or injury (e.g. aging, Aß toxicity, brain trauma, or oxidative stress) is uniquely susceptible to proteolytic cleavage by an apoE cleaving enzyme (AECE) and that the resulting bioactive carboxyl-terminal-truncated fragments, probably together with other AD related factors (e.g., Aß) induce neuropathology and associated behavioral deficits. Thus, AECE represents a new therapeutic target for AD drug development. In addition, protection of the apoE4 fragment interaction with cytoskeletal components of mitochondria might also be beneficial for treatment or prevention from AD.

Recently, we also demonstrated that apoE4 knock-in (ApoE4KI) mice have a significant age-dependent decrease in hilar GABAergic interneurons that correlates with the extent of apoE4-induced impairment of adult hippocampal neurogenesis and learning and memory deficits (Li et al, Cell Stem Cell. 2009, 5:634–645; Andrews-Zwilling et al, J. Neurosci. 2010, in press). In neurotoxic apoE4 fragment transgenic mice, the interneuron loss was even more pronounced and correlated with the extent of learning and memory deficits. The interneuron loss and learning and memory deficits in these mice were prevented by tau removal, and the prevention was abolished by blocking GABA signaling with picrotoxin. In both groups of mice, the GABA receptor potentiator pentobarbital rescued the hippocampal neurogenesis impairment and learning and memory deficits. These findings strongly suggest that apoE4 causes age- and tau-dependent hilar GABAergic interneuron impairment, leading to adult hippocampal neurogenesis impairment and learning and memory deficits in mice.

Some Questions Addressed in Ongoing Studies:

Why is apoE4 more susceptible than apoE3 to proteolysis?

Which enzyme or enzymes are responsible for apoE cleavage?

How do apoE4 fragments cause cytoskeletal disruption and mitochondrial dysfunction?

Can we protect mice or humans from apoE4-related neurodegeneration by blocking its proteolysis?

How is apoE expression regulated in neurons?

Yadong Huang, MD, PhD

Senior InvestigatorGladstone Institute of Neurological DiseaseProfessor of Neurology and PathologyUniversity of California, San Franciscoyhuang@gladstone.ucsf.edu415-734-2000415-355-0824 (F)